WO2010106918A1 - Inkjet printer and inkjet printing method - Google Patents

Abstract

The discharge unit (3) of an inkjet printer (1) is provided with discharge mechanisms (31a-31d) which discharge microdroplets of colored ink, and a discharge mechanism (32) which discharges microdroplets of transparent ink. A colored image is rendered in a colored image printing area on a printing medium (9) by means of the discharge mechanisms (31a-31d). Furthermore, a code image is rendered in the margin area around the colored image printing area, and the colored image on the printing medium (9) is covered with transparent ink by means of the discharge mechanism (32). In the inkjet printer (1), an increase in the abrasion resistance and security of the colored image is realized while lowering the production cost of the inkjet printer (1) device, by means of a single discharge mechanism (32) coating the colored image and rendering the code image by discharging the same transparent ink.

Description

Inkjet printer and inkjet printing method

The present invention relates to an ink jet printer that performs printing by an ink jet method and an ink jet type printing method.

Conventionally, a transparent protective layer has been provided on an image in order to prevent wear and discoloration of the image printed on a print medium such as paper. In recent years, the surface of printed matter has been given gloss by applying a transparent ink on the printed image.

On the other hand, in order to improve security such as preventing counterfeiting of printed matter, holograms and encrypted images (so-called watermarks) are formed on the printed matter. For example, in an electrophotographic printer, a technique for drawing a transparent image on a print medium with transparent toner (so-called security toner) is known.

In the card printer for creating an ID card or the like disclosed in Japanese Patent Application Laid-Open No. 11-268457, two overcoat units for transferring an overcoat film by thermocompression bonding are provided on a plastic card on which images and characters are transferred. It is done. Then, after the overcoat film including the hologram is transferred to the entire surface of the plastic card by one overcoat unit, the protective overcoat film is transferred to the plastic card by the other overcoat unit.

By the way, the card printer disclosed in Japanese Patent Laid-Open No. 11-268457 requires two film transfer processes, which complicates the work related to overcoating of a plastic card, and thus there is a limit to improvement in production efficiency. In addition, since a plurality of overcoat units are required, the structure of the card printer is also complicated. Furthermore, waste such as a holding film for holding the overcoat film before transfer is generated after the film transfer.

The present invention is directed to an ink jet printer and aims to improve the wear resistance and security of colored images on a print medium while reducing the manufacturing cost of the apparatus. Another object of the present invention is to realize the modification of the printing medium and the improvement of the security of the colored image on the printing medium while reducing the manufacturing cost of the apparatus.

The ink jet printer controls a discharge mechanism that discharges a small droplet of transparent ink from a plurality of discharge ports, a moving mechanism that moves a print medium relative to the discharge mechanism, and the discharge mechanism and the moving mechanism. Accordingly, the image processing apparatus includes a print control unit that covers the colored image on the print medium with the transparent ink and draws the encrypted image on the print medium with the transparent ink. As a result, it is possible to improve the wear resistance and security of the colored image on the print medium while reducing the manufacturing cost of the apparatus.

In one preferred embodiment of the present invention, the print medium is in the form of a sheet or a thin plate, and the encrypted image is drawn in a blank area around the colored image on one main surface of the print medium. . More preferably, the encryption image is drawn with the transparent ink by the print control unit in parallel with the covering of the colored image with the transparent ink. More preferably, the ejection mechanism passes through each position of the print medium only once by one relative movement of the print medium, thereby drawing the encrypted image with the transparent ink, and the transparent ink with the transparent image. Colored image covering is complete.

In another preferred embodiment of the present invention, the encrypted image is drawn on the colored image.

In still another embodiment of the present invention, the print medium is a sheet or a thin plate, the colored image is drawn on one main surface of the print medium, and the encrypted image is the other of the print medium. It is drawn on the main surface.

In another aspect of the present invention, an inkjet printer includes a discharge mechanism that discharges microdroplets of transparent ink from a plurality of discharge ports, a moving mechanism that moves a print medium relative to the discharge mechanism, and the discharge mechanism. By controlling the mechanism and the moving mechanism, the transparent ink is uniformly ejected onto the print medium to modify the surface of the print medium on which a colored image is to be printed, and the surface onto the print medium. And a print control unit for drawing an encrypted image with transparent ink. As a result, it is possible to improve the printing medium and improve the security of the colored image on the printing medium while reducing the manufacturing cost of the apparatus.

In one preferred embodiment of the present invention, the print medium is a sheet or thin plate, and the encrypted image is a color image print area in which the color image of the print medium is to be printed. Are drawn in a blank area around the colored image print area. More preferably, the encryption control image is drawn with the transparent ink by the print control unit in parallel with the surface modification of the print medium with the transparent ink. More preferably, the ejection mechanism passes through each position of the print medium only once by one relative movement of the print medium, thereby drawing the encrypted image with the transparent ink, and the transparent ink with the transparent image. The modification of the surface of the print medium is completed.

In another preferred embodiment of the present invention, the print medium is a sheet or thin plate, the colored image is to be drawn on one main surface of the print medium, and the encrypted image is the print medium. Is drawn on the other main surface of.

In an inkjet printer, the transparent ink may be an ultraviolet visible ink. The ink jet printer further includes another discharge mechanism that discharges micro droplets of colored ink from a plurality of discharge ports, and the print control unit controls the other discharge mechanism together with the moving mechanism. The colored image may be drawn on the print medium.

The present invention is also directed to an ink jet printing method.

The above object and other objects, features, aspects, and advantages will become apparent from the following detailed description of the present invention with reference to the accompanying drawings.

It is a figure which shows the inkjet printer which concerns on 1st Embodiment. It is a top view of a printing medium. It is a figure which shows the flow of printing by an inkjet printer. It is a figure which shows a threshold value matrix and an original image abstractly. It is a figure which shows the inkjet printer which concerns on 2nd Embodiment. It is a figure which shows the flow of printing by an inkjet printer. It is a figure which shows the inkjet printer which concerns on 3rd Embodiment. It is a figure which shows the flow of printing by an inkjet printer. It is a figure which shows the inkjet printer which concerns on 4th Embodiment. It is a figure which shows the flow of printing by an inkjet printer. It is a figure which shows the printer system which concerns on 5th Embodiment.

FIG. 1 is a diagram showing a configuration of an inkjet printer 1 according to a first embodiment of the present invention. The ink jet printer 1 is a sheet-fed printing apparatus that sequentially performs color printing on a plurality of print media 9 using an ink jet method.

As shown in FIG. 1, the inkjet printer 1 includes a moving mechanism 2 that moves a plurality of printing media 9 in the (+ Y) direction in FIG. 1, and a minute liquid of ink toward the printing medium 9 that is being transported by the moving mechanism 2. A discharge unit 3 that discharges droplets, a supply unit 51 that supplies the print medium 9 to the moving mechanism 2, a discharge unit 52 that receives the print medium 9 after printing from the transfer mechanism 2, and a print control unit that controls these mechanisms 4 is provided.

The moving mechanism 2 includes a plurality of stages 21 each for sucking and holding one sheet-like print medium 9 (printing paper in the present embodiment), an annular guide 22 for guiding the plurality of stages 21, and a guide. 1 is moved in the (+ Y) direction below the discharge unit 3 (ie, on the (−Z) side) by moving the belt in the counterclockwise direction in FIG. A drive mechanism (not shown) is provided.

The ejection unit 3 includes five ejection mechanisms 31a to 31d and 32, each ejecting micro droplets of ink from a plurality of ejection ports, and the ejection mechanisms 31a to 31d and 32 are arranged in the Y direction in FIG. . In the discharge section 3, the discharge mechanism 31a located closest to the (−Y) side in FIG. 1 discharges K (black) colored ink, and the (+ Y) side discharge mechanism 31b of the discharge mechanism 31a is C (cyan). The (+ Y) side discharge mechanism 31c of the discharge mechanism 31b discharges M (magenta) color ink, and the (+ Y) side discharge mechanism 31d of the discharge mechanism 31c is Y (yellow) color. Ink is ejected. Moreover, in the discharge part 3, the discharge mechanism 32 located in the most (+ Y) side in FIG. 1 discharges a transparent ink. In the present embodiment, an invisible ink (that is, an ultraviolet visible ink) that is visualized by being irradiated with ultraviolet rays is used as the transparent ink.

In the inkjet printer 1, the ejection mechanisms 31 a to 31 d and 32 of the ejection unit 3 extend over the entire width of the printing medium 9 (that is, in the X direction) with respect to the X direction perpendicular to the moving direction (Y direction) of the printing medium 9. The entire length of the printing medium 9 is moved in the (+ Y) direction so that the ejection mechanisms 31a to 31d and 32 pass through each position on the printing medium 9 only once for printing. Printing on the medium 9 is completed. That is, the inkjet printer 1 performs printing (so-called one-pass printing) that does not involve reciprocal movement of the print medium 9 in the X direction.

A computer 7 is connected to the inkjet printer 1, and the original image data and halftone dot formation threshold matrix (also referred to as SPM (Screen Pattern Memory) data) are sent from the computer 7 to the print control unit 4 of the inkjet printer 1. Sent. The original image data is to be drawn in the color image print area 92 set on the (+ Z) side main surface 91 (hereinafter referred to as “first main surface 91”) of the print medium 9 shown in FIG. Multi-tone color image data and multi-tone encrypted image data to be drawn in the margin area 93 around the color image print area 92 are included. An encrypted image is an image that is invisible (or difficult to view) with the naked eye under normal light irradiation conditions, and under special conditions (in this embodiment, ultraviolet light is irradiated). It is an image that can be visually recognized and is also called an invisible image. As the encrypted image, for example, a company logo mark related to the print medium 9 or a serial number for specifying information related to the manufacture of the print medium 9 is drawn.

FIG. 3 is a diagram showing a flow of printing by the ink jet printer 1. In the ink jet printer 1, a halftone dot image signal (hereinafter referred to as “first halftone dot image data”) representing a color image based on the original image data and the threshold matrix in the print control unit 4 (see FIG. 1). ) And a halftone dot image signal representing the encrypted image (hereinafter referred to as “second halftone dot image data”) is generated (step S11). The first halftone dot image data is generated by separating the color image data included in the original image into K, C, M, and Y colors and converting the separated image data into halftone dots using a threshold matrix. And halftone dot image data of K, C, M, and Y colors.

When the original image is halftone (that is, when generating a halftone image representing the original image), the original image 70 is divided into a plurality of regions of the same size as shown in FIG. A repetitive area 71 serving as a unit for dotization is set. The SPM (Screen Pattern Memory) of the print control unit 4 has a matrix space (matrix region) that is a storage area corresponding to one repeating area 71, and each address of the matrix space (that is, each pixel of the repeating area 71 is assigned to each pixel). The threshold value matrix 710 is generated by setting the threshold value to the coordinates (pixels) of the corresponding matrix space.

Conceptually, each repetition region 71 of the original image 70 and the threshold matrix 710 are overlapped, and the gradation level of each pixel in the repetition region 71 is compared with the corresponding threshold value of the threshold value matrix 710, so that the network Whether or not drawing is performed at the position of the pixel on the printing medium 9 which is a dot recording medium (that is, whether or not ink droplets are ejected) is determined. Therefore, if the gradation level of the original image 70 is uniform, drawing is performed on the pixel of the address for which a threshold value smaller than that gradation level is set in the threshold value matrix 710, and is macroscopically uniform. A halftone dot is generated. Actually, since the original image 70 has light and shade (that is, portions of various gradation levels), the state of the halftone dot changes in the repeat area 71 according to the light and shade of the original image 70.

Subsequently, the print medium 9 shown in FIG. 1 is supplied from the supply unit 51 onto the stage 21 and held. The first main surface of the printing medium 9 moving in the (+ Y) direction is controlled by controlling the moving mechanism 2 and the discharging mechanisms 31a to 31d and 32 of the discharging unit 3 based on the first halftone dot image data. A colored image of K, C, M, and Y is ejected toward a colored image print area 92 (see FIG. 2) on 91 to draw a colored image (step S12). Transparent ink is ejected onto each colored ink droplet applied on the printing medium 9 to coat the colored image with the transparent ink (so-called overcoat is performed) (step S13). In the inkjet printer 1, the colored image is drawn on the entire print medium 9 by sequentially drawing a colored image (step S 12) and covering the colored image (step S 13) on each portion of the print medium 9 in the Y direction. Image drawing (step S12) and colored image covering (step S13) are performed in parallel (the same applies to steps S22 and S23 of FIG. 6 described later).

In step S13, each dot of the colored image is covered with a transparent ink dot having the same size. In the highlight portion of the color image, the dot of the color image may be covered with a dot of transparent ink larger than the dot. Thereby, even when the landing position of the transparent ink (that is, the position where the droplet of transparent ink is applied) is slightly deviated from the dot of the color image, the dot of the color image is reliably covered with the transparent ink. . In addition, in the tinted portion of the colored image, the tinted portion may be uniformly covered with the transparent ink over the entire surface, and the total area of the dots of transparent ink applied to the tinted portion is a predetermined area of the tinted portion. The transparent ink is uniformly applied to the tint part by controlling the ejection of the transparent ink so that the ratio (a predetermined ratio greater than 0% and less than 100%, for example, 50%) is achieved. Also good. By making the total area of the dots of the transparent ink smaller than the area of the tint part, drying of the colored ink in the tint part is promoted.

In the inkjet printer 1, the ejection mechanism 32 is controlled based not only on the first halftone dot image data but also on the second halftone dot image data, so that the colored image is covered with the transparent ink in step S13. Transparent toward the blank area 93 on the first main surface 91 of the print medium 9 (in this embodiment, the portion located on the (+ X) side or the (−X) side of the colored image print area 92 in the blank area 93). Ink is ejected, and an encrypted image is drawn with transparent ink in the margin area 93 (step S14). As a result, on the first main surface 91 of the print medium 9 on which the colored image is drawn, the colored image is covered and the encrypted image is drawn on the blank area 93 around the colored image (that is, the colored image is avoided). The drawing of the encrypted image) is performed in parallel with the same transparent ink ejected from the one ejection mechanism 32.

Then, by one relative movement in the (+ Y) direction of the print medium 9 with respect to the discharge unit 3, the discharge mechanisms 31a to 31d and 32 pass through the respective positions on the print medium 9 only once, and a colored image with colored ink is obtained. Drawing, covering of a colored image with transparent ink, and drawing of an encrypted image with transparent ink are completed. Thereafter, the print medium 9 is collected by the discharge unit 52. In the print medium 9 in which the printing by the ink jet printer 1 is completed, the color image in the color image print area 92 is covered with the transparent ink, and the wear resistance of the color image is improved. In addition, since the encrypted image is drawn, it is difficult to accurately copy or forge the print medium 9 on which the colored image is printed (that is, accurately copy or forge the colored image and the encrypted image). As a result, the distinction between the original print medium 9 and a copy of the print medium 9 is facilitated, and the security of the colored image on the print medium 9 is improved. In the inkjet printer 1, the above-described printing is sequentially performed on a plurality of print media 9 (the same applies to other embodiments below).

As described above, in the inkjet printer 1, the covering of the colored image and the drawing of the encrypted image are ejected from the one ejection mechanism 32 on the first main surface 91 of the printing medium 9 on which the colored image is drawn. Of transparent ink. Thereby, the structure of the inkjet printer 1 is simplified, and it is possible to improve the wear resistance and security of colored images while reducing the manufacturing cost of the apparatus. Moreover, the printing cost to the printing medium 9 can also be reduced.

In the inkjet printer 1, the ultraviolet visible ink is used as the transparent ink, so that reading of the encrypted image from the printing medium 9 is relatively inexpensive and easy to handle without using expensive equipment or equipment. It can be easily performed using black light or the like. Furthermore, since the encrypted image has multiple gradations, it is impossible to detect the encrypted image due to the insufficient discharge amount of the transparent ink, and the encrypted image is not revealed under normal illumination due to the excessive discharge amount of the transparent ink. High-precision drawing is realized.

In the ink jet printer 1, the encrypted image is drawn while avoiding the colored image, so that the discharge port used for drawing the encrypted image and the discharge port used for covering the colored image in the discharge mechanism 32 are different. Is done. Thereby, the discharge control of the transparent ink from the discharge port used for covering the colored image of the discharge mechanism 32 is performed based only on the first halftone dot image data, and from the discharge port used for drawing the encrypted image. Transparent ink ejection control is performed based only on the second halftone dot image data. As a result, the control of the discharge mechanism 32 is simplified. In addition, since the encrypted image is drawn in the blank area 93 around the colored image, it is possible to easily cover the colored image and draw the encrypted image in parallel. As a result, printing on the print medium 9 can be performed quickly.

As described above, in the inkjet printer 1, the covering of the color image with the transparent ink and the drawing of the encrypted image are performed by one-pass printing, and thus the structure of the moving mechanism 2 that moves the print medium 9 relative to the ejection unit 3. Can be simplified, and printing on the print medium 9 can be performed more quickly.

By the way, if a colored image is drawn on the print medium 9 by a device different from the ink jet printer 1, the color on the print medium 9 is discharged before the transparent ink is ejected to the print medium 9 in the ink jet printer 1. The relative position between the colored image and the ejection mechanism 32 needs to be adjusted by reading the image with a scanner or the like. On the other hand, in the inkjet printer 1 according to the present embodiment, the moving mechanism 2 used for covering the colored image and drawing the encrypted image is controlled by the print control unit 4 together with the discharge mechanisms 31a to 31d of the discharge unit 3. Thus, a colored image is drawn on the print medium 9. For this reason, it is not necessary to adjust the relative position between the colored image and the ejection mechanism 32 as described above, and the covering of the colored image and the drawing of the encrypted image are simplified. Furthermore, since the drawing of the colored image is performed by the same ink jet method as the covering of the colored image and the drawing of the encrypted image, the structure of the ejection unit 3 can be simplified. In addition, since the color image is drawn approximately in parallel with the covering of the color image and the drawing of the encrypted image (more specifically, approximately in parallel while slightly preceding), the printing on the print medium 9 is more performed. Done quickly.

In the above-described embodiment, the encrypted image is described as being drawn in the margin area 93 around the colored image on the first main surface 91 of the print medium 9 shown in FIG. May be drawn on the color image drawn in the color image print area 92. When the encrypted image is drawn on the color image, in steps S13 and S14, for example, the discharge amount of the transparent ink from the discharge port group facing the color image print region 92 of the discharge mechanism 32 is equal to the color image print region 92. The predetermined amount is set so that the entire area is uniformly covered with the transparent ink without any gaps, and the discharge amount of the transparent ink from the discharge port corresponding to each dot of the encrypted image is set based on the second halftone dot image data. The print control unit 4 performs control to increase the predetermined amount by about 20% to 30%.

As a result, the colored image printing region 92 on which the colored image is drawn is covered with the transparent ink over the entire surface, and the height of the portion corresponding to the encrypted image in the coating layer of the transparent ink is made higher than the surroundings. . Thus, by drawing the encrypted image on the colored image, it is possible to make it more difficult to visually recognize the encrypted image in a state where normal light is irradiated. The encrypted image may be drawn on both the color image and the blank area 93.

Next, an ink jet printer according to a second embodiment of the present invention will be described. FIG. 5 is a diagram illustrating a configuration of an inkjet printer 1a according to the second embodiment. The configuration of the inkjet printer 1a is the same as that of the inkjet printer 1 shown in FIG. 1 except that the moving mechanism 2 includes a reversing mechanism 24 below the guide 22. In the following description, the configuration of the inkjet printer 1a corresponds to each configuration of the inkjet printer 1. The same reference numerals are given to the components to be performed.

FIG. 6 is a diagram showing a flow of printing by the inkjet printer 1a. In the inkjet printer 1a, as in the first embodiment, the print control unit 4 generates first halftone dot image data representing a colored image and second halftone dot image data representing an encrypted image. (Step S21). Subsequently, the print medium 9 is supplied and held on the stage 21 from the supply unit 51, and the print control unit 4 controls the moving mechanism 2 and the discharge mechanisms 31a to 31d and 32 of the discharge unit 3, thereby the print medium. The colored image is drawn in the colored image print area 92 (see FIG. 2) of the first main surface 91 of 9 (step S22), and the colored image is covered with the transparent ink (step S23).

The print medium 9 in which the drawing of the colored image and the covering of the colored image have been completed moves counterclockwise in FIG. 5 as the belt in the guide 22 of the moving mechanism 2 moves, and is collected by the discharge unit 52. The reversing mechanism 24 is reached. Then, the printing medium 9 is reversed by the reversing mechanism 24, and the first main surface 91 that is one main surface on which the colored image is drawn is sucked and held by the stage 21 (step S24).

Thereafter, when the belt in the guide 22 further moves, the print medium 9 moves counterclockwise and is positioned below the discharge unit 3, and the second main surface 94, which is the other main surface of the print medium 9. (Refer to FIG. 2) faces the discharge mechanism 32. In the ink jet printer 1a, the printing mechanism 4 controls the moving mechanism 2 and the ejection mechanism 32, whereby the transparent ink is ejected toward the second main surface 94 of the print medium 9, and the second main surface 94 is discharged. The encryption image is drawn (step S25). The print medium 9 on which the drawing of the encrypted image is completed is collected by the discharge unit 52.

In the print medium 9, as in the first embodiment, the colored image is covered with the transparent ink to improve the wear resistance of the colored image, and the encrypted image is drawn, so that the colored image on the print medium 9 is drawn. Image security is improved. In the ink jet printer 1 a, similarly to the ink jet printer 1, the covering of the colored image and the drawing of the encrypted image are performed by the same transparent ink ejected from the one ejection mechanism 32. Thereby, without complicating the structure of the inkjet printer 1a, it is possible to improve the wear resistance and security of colored images while reducing the manufacturing cost of the apparatus. Moreover, the printing cost to the printing medium 9 can also be reduced.

In the inkjet printer 1a, an encrypted image is drawn on a second main surface 94 different from the first main surface 91 on which a colored image is drawn. For this reason, when the ejection of the transparent ink from the ejection mechanism 32 is controlled, it is not necessary to merge the first halftone dot image data and the second halftone dot image data. Therefore, the control of the discharge mechanism 32 is simplified.

In the inkjet printer 1a, after the encryption image is drawn on the second main surface 94, the color image may be drawn on the first main surface 91 and the color image may be covered. In addition to drawing the encrypted image on the second main surface 94, the encrypted image may be drawn on the blank area 93 or the colored image of the first main surface 91.

Next, an ink jet printer according to a third embodiment of the present invention will be described. FIG. 7 is a diagram illustrating a configuration of an inkjet printer 1b according to the third embodiment. The configuration of the inkjet printer 1b is the same as that of FIG. 1 except that the discharge mechanism 32 that discharges transparent ink is disposed on the (−Y) side of the discharge mechanisms 31a to 31d that discharge K colored ink. In the following description, components corresponding to those of the inkjet printer 1 are denoted by the same reference numerals.

In the ink jet printer 1b, the surface of the print medium 9 on which the color image is to be printed is modified by uniformly ejecting the transparent ink onto the print medium 9 before drawing the color image. So-called undercoat is performed). Hereinafter, the flow of printing by the inkjet printer 1b will be described with reference to FIG. In the inkjet printer 1b, as in the first embodiment, the print control unit 4 generates first halftone dot image data representing a colored image and second halftone dot image data representing an encrypted image. (Step S31).

Subsequently, the print medium 9 is supplied and held on the stage 21 from the supply unit 51, and the print control unit 4 controls the discharge mechanism 32 of the moving mechanism 2 and the discharge unit 3. Transparent ink is uniformly ejected from the ejection port facing the colored image printing area 92 (see FIG. 2) of the print medium 9 on which the colored image is to be drawn, toward the colored image printing area 92, Surface modification of the colored image print area 92 is performed on the first main surface 91 (see FIG. 2) of the print medium 9 (step S32). Further, the discharge of the transparent ink from the discharge ports facing the blank area 93 (see FIG. 2) around the colored image print region 92 among the plurality of discharge ports of the discharge mechanism 32 is based on the second halftone dot image data. Thus, in parallel with step S32, the encrypted image is drawn in the blank area 93 (that is, avoiding the colored image print area 92) (step S33).

In the ink jet printer 1b, the moving mechanism 2 and the discharge mechanisms 31a to 31d of the discharge unit 3 are controlled by the print control unit 4, so that the portion that passes under the discharge mechanism 32 in the colored image print region 92 (that is, the surface modification). Colored ink is ejected toward the post-quality colored image printing area 92), and a colored image is drawn (step S34). In the inkjet printer 1b, the surface modification, the drawing of the encrypted image (steps S32 and S33), and the drawing of the colored image (step S34) are sequentially performed on each portion of the print medium 9 in the Y direction. As a result, the modification of the surface and the drawing of the encrypted image (steps S32 and S33) and the drawing of the colored image (step S34) on the entire print medium 9 are performed approximately in parallel.

In the ink jet printer 1b, the discharge mechanism 32, 31a to 31d passes through each position on the print medium 9 only once by the relative movement of the print medium 9 in the (+ Y) direction with respect to the discharge unit 3, and the transparent ink The surface modification of the print medium 9 by the above, the drawing of the encrypted image by the transparent ink, and the drawing of the colored image by the colored ink are completed. Thereafter, the print medium 9 is collected by the discharge unit 52.

In the printing medium 9 that has been printed by the inkjet printer 1b, the surface of the colored image printing area 92 is changed by performing surface modification with transparent ink on the colored image printing area 92 before the colored image is drawn. It is in a state suitable for colored ink used for drawing a colored image. As a result, high-precision and high-quality color image drawing on the color image print area 92 is realized. In addition, since the encrypted image is drawn on the print medium 9, it is difficult to copy or forge the print medium 9 on which the color image is printed, and the security of the color image on the print medium 9 is improved.

In the inkjet printer 1b, the surface modification of the printing medium 9 and the drawing of the encrypted image are performed by the same transparent ink ejected from the one ejection mechanism 32. Thereby, without complicating the structure of the ink jet printer 1b, the surface modification of the print medium 9, the drawing of a color image with high accuracy and high quality by the modification, and the color image on the print medium 9 can be performed. Security improvement can be realized while reducing the manufacturing cost of the apparatus. Moreover, the printing cost to the printing medium 9 can also be reduced.

As described above, in the inkjet printer 1b, the encrypted image is drawn in the blank area 93 around the colored image, and the surface modification of the print medium 9 and the drawing of the encrypted image can be easily performed in parallel. Thereby, the printing with respect to the printing medium 9 can be performed rapidly. In the inkjet printer 1b, the blank area 93 may be surface-modified with transparent ink. In this case, for example, the discharge amount of the transparent ink from the discharge port group facing the blank area 93 of the discharge mechanism 32 is set to a predetermined amount so that the transparent ink is uniformly discharged to the blank area 93. Based on the second halftone dot image data, the print control unit 4 controls to increase the discharge amount of the transparent ink from the discharge port corresponding to each dot of the encrypted image by about 20% to 30% of the predetermined amount. .

In the inkjet printer 1b, as in the first embodiment, the ultraviolet visible ink is used as the transparent ink, so that the encrypted image can be easily read from the print medium 9. Further, since the encrypted image has multiple gradations, highly accurate drawing of the encrypted information is realized.

By the way, if drawing of a colored image on the printing medium 9 is performed by an apparatus different from the inkjet printer 1b, the positional information of the colored image printing area 92 on the printing medium 9 is obtained before drawing of the colored image. It is necessary to adjust the relative position between the color image printing area 92 and the ejection mechanism of the apparatus that is obtained and used for drawing the color image. On the other hand, in the inkjet printer 1b according to the present embodiment, the moving mechanism 2 used for surface modification of the printing medium 9 and drawing of the encrypted image is performed by the printing control unit 4 together with the discharging mechanisms 31a to 31d of the discharging unit 3. The colored image is drawn on the printing medium 9 under the control. For this reason, it is not necessary to adjust the relative position between the colored image printing region 92 and the discharge mechanism of the apparatus used for drawing the colored image, and the drawing of the colored image is simplified. Furthermore, since the colored image is drawn by the same ink jet method as the surface modification of the printing medium 9 and the drawing of the encrypted image, the structure of the ejection unit 3 can be simplified. In addition, the colored image is drawn almost in parallel with the surface modification of the printing medium 9 and the drawing of the encrypted image, so that the printing on the printing medium 9 is performed more quickly.

Next, an inkjet printer according to a fourth embodiment of the present invention will be described. FIG. 9 is a diagram illustrating a configuration of an inkjet printer 1c according to the fourth embodiment. The configuration of the ink jet printer 1c is such that a reversing mechanism 24 similar to that of the ink jet printer 1a according to the second embodiment (see FIG. 5) is provided below the guide 22, and the second main surface 94 of the print medium 9 (FIG. 2). 7) is the same as that of the ink jet printer 1b shown in FIG. 7 except that the encrypted image is drawn. In the following description, the same reference numerals are given to the components corresponding to the respective components of the ink jet printer 1b.

As shown in FIG. 10, in the ink jet printer 1c, the print control unit 4 generates first halftone dot image data representing a colored image and second halftone dot image data representing an encrypted image (step S41). ). Subsequently, the print medium 9 is supplied and held on the stage 21 from the supply unit 51, and the print control unit 4 controls the discharge mechanisms 32 and 31 a to 31 d of the discharge unit 3, so that the print medium The transparent ink is uniformly ejected toward the 9 colored image printing areas 92 (see FIG. 2), the surface modification of the colored image printing areas 92 is performed, and the colored images are printed in the colored image printing areas 92 after the surface modification. Is drawn (steps S42 and S43).

The print medium 9 on which the surface modification and the drawing of the colored image have been completed reaches the reversing mechanism 24 without being collected by the discharge unit 52, and is reversed by the reversing mechanism 24 (step S44). Thereafter, the print medium 9 is moved below the discharge unit 3, and the moving mechanism 2 and the discharge mechanism 32 are controlled by the print control unit 4, whereby the encrypted image is drawn on the second main surface 94 of the print medium 9. Performed (step S45). The print medium 9 on which the drawing of the encrypted image is completed is collected by the discharge unit 52.

In the inkjet printer 1c, the surface modification of the printing medium 9 and the drawing of the encrypted image are performed by the same transparent ink ejected from the one ejection mechanism 32. Thus, as in the third embodiment, without complicating the structure of the inkjet printer 1c, the surface modification of the print medium 9, and the drawing of a color image with high accuracy and high quality by the modification, In addition, it is possible to improve the security of the colored image on the print medium 9 while reducing the manufacturing cost of the apparatus. Moreover, the printing cost to the printing medium 9 can also be reduced. Furthermore, the control of the ejection mechanism 32 is simplified by drawing the encrypted image on the second main surface 94.

Next, an ink jet printer according to a fifth embodiment of the present invention will be described. FIG. 11 is a diagram illustrating a configuration of a printer system 100 including the inkjet printer 1d according to the fifth embodiment. As shown in FIG. 11, the printer system 100 includes an offset printing apparatus 101 and a scanner 102 in addition to the inkjet printer 1d. The configuration of the ink jet printer 1d is the same as that of the ink jet printer 1 shown in FIG. 1 except that the discharge mechanisms 31a to 31d for discharging colored ink are not provided in the discharge section 3. The components corresponding to the respective components are denoted by the same reference numerals.

In the printer system 100, the offset printing apparatus 101 prints a color image in the color image print area 92 (see FIG. 2) of the print medium 9, and the first main surface 91 (FIG. 2) of the print medium 9 on which the color image is printed. Reference) is imaged by the scanner 102. In the inkjet printer 1d, the print control unit 4 moves the moving mechanism 2 based on the information indicating the dot position of the colored ink and the position of the margin area 93 (see FIG. 2) in the colored image printing area 92 obtained from the output of the scanner 102. By controlling the discharge mechanism 32 (see FIG. 1) of the discharge unit 3, the color image in the color image print area 92 is covered with the transparent ink, and the encrypted image with the transparent ink is drawn in the blank area 93.

In the inkjet printer 1d of the printer system 100, similarly to the first embodiment, the covering of the colored image and the drawing of the encrypted image are performed on the first main surface 91 of the printing medium 9 on which the colored image is drawn. The same transparent ink discharged from the mechanism 32 is used. Thereby, without complicating the structure of the inkjet printer 1d, it is possible to improve the wear resistance and security of colored images while reducing the manufacturing cost of the apparatus.

Note that in the printer system 100, the color image print information in the offset printing apparatus 101 (that is, information indicating the dot position of the color ink) and the information indicating the position of the margin area 93 on the print medium 9 are acquired in advance. In this case, the scanner 102 may be omitted. Further, instead of the offset printing apparatus 101, another printing apparatus such as an electrophotographic printer may be provided.

In the inkjet printer 1d, when the entire color image print area 92 is uniformly covered with transparent ink, the approximate positions of the color image print area 92 and the blank area 93 need only be detected. Therefore, the scanner 102 can be omitted from the printer system 100 if each stage 21 of the ink jet printer 1d is provided with a guide or the like for positioning the print medium 9 by contacting the edge of the print medium 9.

As mentioned above, although embodiment of this invention has been described, this invention is not limited to the said embodiment, A various change is possible.

In the ink jet printers according to the third and fourth embodiments, if necessary, a discharge mechanism that discharges transparent ink is also provided on the (+ Y) side of the discharge mechanism 31d of the discharge unit 3, and a colored image using the transparent ink is provided. The coating may be performed.

In the ink jet printers according to the first to fourth embodiments, the ejection mechanisms 31b to 31d may be omitted from the ejection unit 3 and used as a monochrome printer. Further, the encrypted image may be drawn with dots of a single size instead of multi-tone dots of transparent ink (that is, dots of a plurality of types).

In the ink jet printer according to the above embodiment, the width in the X direction of each discharge head of the discharge unit 3 is smaller than the width in the X direction of the print medium 9, and the reciprocating movement of the discharge unit 3 in the X direction and the print medium 9. The printing on the print medium 9 may be performed by performing the movement in the (+ Y) direction in parallel. Further, the moving mechanism 2 is not necessarily a mechanism that moves the printing medium 9. For example, the moving mechanism 2 moves the discharging unit 3 (that is, the discharging mechanisms 31 a to 31 d, 32) to move the printing medium 9 to the discharging unit 3. It may be a mechanism that moves relative to.

In the above-described inkjet printer, for example, printing may be performed on a so-called web that is continuous paper. Further, in an inkjet printer, it is not always necessary to print on a sheet-like print medium 9 such as paper or film, and printing may be performed on a thin plate-like print medium or other various print media. .

Although the present invention has been described in detail, the above description is illustrative and not restrictive. Therefore, it will be understood that many variations and embodiments are possible without departing from the scope of the invention.

DESCRIPTION OF SYMBOLS 1,1a-1d Inkjet printer 2 Movement mechanism 4 Print control part 9 Print medium 32 Discharge mechanism 91 1st main surface 92 Colored image printing area 93 Margin area 94 2nd main surface S11-S14, S21-S25, S31-S34, Steps S41 to S45

Claims (17)

1. An inkjet printer (1, 1a, 1d),
   A discharge mechanism (32) for discharging microdroplets of transparent ink from a plurality of discharge ports;
   A moving mechanism (2) for moving the print medium (9) relative to the discharge mechanism (32);
   By controlling the discharge mechanism (32) and the moving mechanism (2), the colored image on the print medium (9) is covered with the transparent ink, and on the print medium (9) with the transparent ink. A print control unit (4) for drawing an encrypted image;
   Is provided.
2. The inkjet printer according to claim 1,
   The print medium (9) is a sheet or a thin plate,
   The encrypted image is drawn in a blank area (93) around the colored image on one main surface (91) of the print medium (9).
3. The inkjet printer according to claim 2,
   The printing control unit (4) draws the encrypted image with the transparent ink in parallel with the covering of the colored image with the transparent ink.
4. The inkjet printer according to claim 3,
   Drawing the cipher image with the transparent ink by causing the ejection mechanism (32) to pass through each position of the print medium (9) only once by one relative movement of the print medium (9), and Covering the colored image with the transparent ink is completed.
5. The inkjet printer according to claim 1,
   The encrypted image is drawn on the colored image.
6. The inkjet printer according to claim 1,
   The print medium (9) is a sheet or a thin plate,
   The colored image is drawn on one main surface (91) of the print medium (9), and the encrypted image is drawn on the other main surface (94) of the print medium (9).
7. The inkjet printer according to claim 1,
   The transparent ink is an ultraviolet visible ink.
8. The inkjet printer according to claim 1,
   Further provided with another discharge mechanism (31a to 31d) for discharging fine droplets of colored ink from a plurality of discharge ports,
   The colored image is drawn on the print medium (9) by controlling the other discharge mechanism (31a to 31d) together with the moving mechanism (2) by the print control unit (4).
9. An inkjet printer (1b, 1c),
   A discharge mechanism (32) for discharging microdroplets of transparent ink from a plurality of discharge ports;
   A moving mechanism (2) for moving the print medium (9) relative to the discharge mechanism (32);
   By controlling the discharge mechanism (32) and the moving mechanism (2), the print medium (9) on which a colored image is to be printed by uniformly discharging the transparent ink onto the print medium (9). A print control unit (4) for modifying the surface of
   Is provided.
10. The inkjet printer according to claim 9, wherein
    The print medium (9) is a sheet or a thin plate,
    In the main image (91) on which the color image print area (92) on which the color image of the print medium (9) is to be printed is set, the encrypted image is printed on the color image print area (92). It is drawn in the surrounding margin area (93).
11. The inkjet printer according to claim 10,
    The printing control unit (4) draws the encrypted image with the transparent ink in parallel with the surface modification of the printing medium (9) with the transparent ink.
12. The inkjet printer according to claim 11,
    Drawing the cipher image with the transparent ink by causing the ejection mechanism (32) to pass through each position of the print medium (9) only once by one relative movement of the print medium (9), and The modification of the surface of the print medium (9) with the transparent ink is completed.
13. The inkjet printer according to claim 9, wherein
    The print medium (9) is a sheet or a thin plate,
    The colored image is to be drawn on one main surface (91) of the print medium (9), and the encrypted image is drawn on the other main surface (94) of the print medium (9).
14. The inkjet printer according to claim 9, wherein
    The transparent ink is an ultraviolet visible ink.
15. The inkjet printer according to claim 9, wherein
    Further provided with another discharge mechanism (31a to 31d) for discharging fine droplets of colored ink from a plurality of discharge ports,
    The colored image is drawn on the print medium (9) by controlling the other discharge mechanism (31a to 31d) together with the moving mechanism (2) by the print control unit (4).
16. An inkjet printing method,
    a) By ejecting transparent ink micro droplets from a plurality of ejection openings of the ejection mechanism (32) and moving the printing medium (9) relative to the ejection mechanism (32), the printing medium ( 9) coating the above colored image with the transparent ink;
    b) Discharging the transparent ink micro droplets from the plurality of discharge ports and moving the print medium (9) relative to the discharge mechanism (32) Drawing an encrypted image with the transparent ink,
    Is provided.
17. An inkjet printing method,
    a) By ejecting transparent ink micro droplets from a plurality of ejection openings of the ejection mechanism (32) and moving the printing medium (9) relative to the ejection mechanism (32), the printing medium ( 9) modifying the surface of the print medium (9) on which a colored image is to be printed by uniformly discharging the transparent ink on the surface;
    b) Discharging the transparent ink micro droplets from the plurality of discharge ports and moving the print medium (9) relative to the discharge mechanism (32) Drawing an encrypted image with the transparent ink,
    Is provided.

Images